Hot swap circuit

ABSTRACT

In one embodiment, a hot swap circuit is disclosed. The hot swap circuit includes a first switch connected to a power input line. The hot swap circuit also includes a first capacitor connected to the first switch that is charged when the first switch is closed. The hot swap circuit further includes a second switch connected to the first switch and the first capacitor. The hot swap circuit additionally includes an input capacitor connected to the second switch and located in parallel with an input line to a power system. When the second switch is closed, the input capacitor is charged.

RELATED APPLICATION

The present application is a Continuation application of U.S. patentapplication Ser. No. 14/824,282, filed Aug. 12, 2015, entitled “HOT SWAPCIRCUIT”, by Michael Robert Grant et al., the contents of which ishereby incorporated by reference

TECHNICAL FIELD

The present disclosure relates generally to electronic devices, and,more particularly, to a hot swap circuit.

BACKGROUND

Many devices, such as networking and computing devices (e.g., servers,switches, disk arrays, etc.), require the ability to update or replacefaulty equipment without interrupting the functioning of the rest of thesystem. For example, a device may have a backplane to which a number ofremovable computing modules can be coupled. During operation of thedevice, modules may be added, removed, or replaced, as needed (e.g., toincrease functionality of the device, to replace a failing module,etc.). However, inrush currents when making such changes may berelatively high. To protect against such currents, a hot swap circuitmay be used to regulate the inrush current to a module while makingchanges to the modules of the device.

BRIEF DESCRIPTION OF THE DRAWINGS

The embodiments herein may be better understood by referring to thefollowing description in conjunction with the accompanying drawings inwhich like reference numerals indicate identically or functionallysimilar elements, of which:

FIG. 1 illustrates an example hot swap circuit;

FIG. 2 illustrates an example graph of the maximum safe operating area(SOA) of a transistor;

FIG. 3 illustrates another example hot swap circuit;

FIG. 4 illustrates an example graph illustrating the operation of thehot swap circuit of FIG. 3;

FIG. 5 illustrates another example hot swap circuit; and

FIG. 6 illustrates an example simplified procedure for operating a hotswap circuit.

DESCRIPTION OF EXAMPLE EMBODIMENTS Overview

According to one or more embodiments of the disclosure, a hot swapcircuit is disclosed. The hot swap circuit includes a first switchconnected to a power input line. The hot swap circuit also includes afirst capacitor connected to the first switch that is charged when thefirst switch is closed. The hot swap circuit further includes a secondswitch connected to the first switch and the first capacitor. The hotswap circuit additionally includes an input capacitor connected to thesecond switch and located in parallel with an input line to a powersystem. When the second switch is closed, the input capacitor ischarged.

In further embodiments, a method is disclosed. The method includesclosing a first switch in a hot swap circuit to charge a first capacitorconnected to the first switch. The method also includes opening thefirst switch. The method further includes closing a second switch in thehot swap circuit to transfer charge from the first capacitor to an inputcapacitor connected to the second switch and located in parallel with aninput line to a power system, while the first switch is held open. Themethod additionally includes closing the first and second switches aftera predefined period of time, to complete charging of the input capacitorto a final input voltage level.

In other embodiments, a hot swap circuit is disclosed. The hot swapcircuit includes first storage means for storing charge supplied by apower supply. The hot swap circuit also includes second storage meansfor storing an input voltage to be supplied to a power system. The hotswap circuit further includes means for transferring charge from thefirst storage means to the second storage means.

DESCRIPTION

Various hot swap circuit designs are provided herein that are operableto protect against large inrush currents, such as when a hardware moduleis plugged into a live computing device. In some aspects of theteachings herein, inrush of a current to a bulk capacitor of a hot swapcircuit may be prevented via intermediary circuitry. Such intermediarycircuitry may include, for example, an intermediary capacitor and/orinductor, to trickle charge the input bulk capacitor for the hot swapcircuit. Doing so may allow for the use of smaller switches,

Referring now to FIG. 1, an example hot swap circuit is shown, accordingto some embodiments. As shown, system 100 may generally include a powersystem 104 and a hot swap circuit 102 powered by a power source 106. Ingeneral, hot swap circuit 102 may operate to prevent a large inrushcurrent from power source 106 during a startup event (e.g., a new moduleis plugged into a running computing device, etc.). Power system 104 maywork in conjunction with hot swap circuit 102 to step down the suppliedvoltage from power source 106 and hot swap circuit 102 into a lowervoltage that may be adjusted into any number of different outputvoltages by point of load converters (POLs) 122 (e.g., a first POL, asecond POL, etc.).

In various embodiments, power system 104 may include a switch 112 inseries with the input line 128 to power system 104 and an inductor 116coupled to switch 112. Running parallel off of input line 128 to powersystem 104 are switches 114, capacitor 118, and a resistor 120. Switches112 and 114 may comprise MOSFETs or other suitable components that areoperable to control the flow of current through power system 104. Aswould be appreciated by one skilled in the art, switches 112-114,inductor 116, capacitor 118, and resistor 120 may be sized accordingly,to step down the input voltage provided to power system 104 via line 128to a lower voltage, as desired. For example, as shown, the components ofpower system 104 may be operable to step down a 50V input voltage to a10V output voltage provided to POLs 122. For example, inductor 116,capacitor 118, and resistor 120 may form an RLC low-pass filter and maybe sized according to a desired corner frequency (ω_(c)) and dampingfactor (ζ) as follows:

$\omega_{c} = \frac{1}{\sqrt{LC}}$$\varsigma = {\frac{1}{2\; R}\sqrt{\frac{L}{C}}}$where L is the inductance of inductor 116, R is the resistance ofresistor 120, and C is the capacitance of capacitor 118.

As noted previously, POLs 122 may be operable to provide voltage to anynumber of different loads (e.g., pins, other electrical connectors,etc.). In one embodiment, POLs 122 may comprise a voltage divider thatdivides the resulting output voltage from switches 112-114, inductor116, capacitor 118, and resistor 120. For example, assume that powersource 106 supplies 50 Volts (V) at 10 Amperes (A) within system 100. Insuch a case, 50V may be supplied to power system 104 via input line 128.In turn, power system 104 may step down the 50V to 10V or any otherlower voltage. In turn, POLs 122 may be configured to convert theresulting 10V into the desired load voltages (e.g., the first POL mayoutput a voltage of 3.3V, the second POL may output a voltage of 2.5V,the third POL may output a voltage of 1.0V, etc.). In other embodiments,other step down circuits may be used in power system 106, to convert theinput voltage on input line 128 of power system 104 to a lower voltage.

In the example shown in FIG. 1, hot swap circuit 102 may include aswitch 108 in series with power source 106 along power input line 124. Acontrol signal may be provided to switch 108 to actuate switch 108. Forexample, a microcontroller or other control circuitry (not shown) mayprovide a control signal to switch 108 to open or close switch 108. Hotswap circuit 102 may also include an input capacitor 110 located alongline 126 that is in parallel to input line 128 of power system 106.Since power system 106 and other similar step down circuits do not haveinductors directly at their power inputs, capacitor 110 may berelatively large, to filter the voltage ripple in system 100. Forexample, capacitor 110 may be a 47 micro Farad (μF), aluminumelectrolytic capacitor, if the voltages and currents shown are used.Other sizes of capacitor 110 may also be used, if other voltages andcurrents are used. In one embodiment, switch 108 may comprise a MOSFETof suitable properties, although other switching mechanisms may also beused, in further embodiments.

Referring now to FIG. 2, an example graph of the maximum safe operatingarea (SOA) of a transistor is shown, according to one embodiment. Asshown, graph 200 depicts the time-varying operational responses of anexemplary MOSFET that may be used for switch 108 in hot swap circuit102. In particular, graph 200 maps the drain-to-source current (I_(D))for an exemplary MOSFET to its drain-to-source voltage (V_(DS)) as afunction of time, thereby defining the minimum SOA for the MOSFET. Thismapping is shown on a logarithmic scale and assumes several conditionsfor the MOSFET such as a single input pulse and the temperature range ofthe device. For example, one exemplary MOSFET that may exhibit thebehavior shown in graph 200 is the IRFP2907PBF power MOSFET byInternational Rectifier™. Other transistors may also be used, in otherembodiments.

While hot swap circuit 102 may be operable to provide protection againstinrush currents during a startup event, several observations can be madewith respect to graph 200 and switch 108. First, switch 108 may requirea longer turn on time, to ensure there is no inrush current to system100 during a startup event. For example, the turn on time for switch 108may be 10 milliseconds (ms) or even higher, depending on theimplementation. Second, from graph 200, the I_(D) currents within theSOA for the exemplary MOSFET decrease as the V_(DS) voltages and turn ontimes increase.

Thus, a number of challenges exist with respect to hot swap circuitdesigns that rely on a single FET acting as a variable resistor to limitthe inrush current into the bulk input capacitor(s) of the circuit.Notably, such designs require the FET to have adequate SOA performance,to survive the power dissipation on startup, while simultaneously havinga resistance low enough to safely pass the board's maximum current drawafter the board has booted up. To satisfy both conditions, the singleFET must be relatively large. In addition, the stress on the FET causedby this power dissipation necessitates careful regulation and monitoringto ensure that the FET does not get damaged. As board power increases,the size and complexity of the hot swap circuit also increases, makingsimpler and more scalable solutions of interest.

Referring now to FIG. 3, another example hot swap circuit is shown,according to various embodiments. As shown, assume that system 300includes the same power system 104 and power source 106 as that ofsystem 100. However, system 300 shown may include a hot swap circuit 302having a different configuration than that of hot swap circuit 102.Notably, whereas hot swap circuit 102 has a single switch 108 in serieswith power source 106 along power input line 124, hot swap circuit 302instead includes a first switch 304 and a second switch 306 locatedalong the same line 124. In various embodiments, hot swap circuit 302also includes a first capacitor 308 located along a first line 312 and asecond capacitor 310 located along a second line 314. Capacitors 308 and310 may each be single capacitors or, alternatively, capacitors that arein parallel along lines 312, 314. As would be appreciated, capacitors inparallel may act as a single capacitor having a capacitance equal to thesum of the capacitances of the capacitors. In other embodiments, eitheror both of capacitors 310, 312 may comprise capacitors in series.

During operation, both switches 304 and 306 may be held open initially,thereby preventing power from power source 106 from being transferredinto hot swap circuit 302, until hot swap circuit 302 is ready to becharged. At such a time, switch 304 may be closed first, while holdingswitch 306 open. In doing so, first capacitor 308 may be charged up to acharged voltage level (e.g., based on the voltage of power source 106).For example, if power source 106 supplies 50V (e.g., as a backplanevoltage), first capacitor 306 may be charged based on this voltage, whenswitch 304 is closed. Any number of other positive and/or negativevoltages and/or currents may be supplied by power source 106, in otherembodiments.

Once the voltage across first capacitor 308 reaches its desired charge,capacitor 308 effectively acts as an open circuit at which point switch304 may be opened. Subsequent to re-opening switch 304, switch 306 maybe closed. Once this occurs, the stored energy in capacitor 308 may betransferred into capacitor 310, the bulk input capacitor for input line128 to power system 104.

In various embodiments, switches 304 and 306 may alternately be openedand closed any number of times, to charge input capacitor 310 to adesired voltage level. In other words, the basic principle of operationof hot swap circuit 302 is to slowly transfer energy first from powersource 106 to capacitor 308 and then from capacitor 308 to inputcapacitor 310 by alternate operation of switches 304-306.

The intermediate capacitor 308 may be of much smaller capacitance thanthat of input capacitor 310 which, consequently, also means thatcapacitor 308 may be much smaller physically than that of capacitor 310.Notably, inrush current (i) in hot swap circuit 302 be calculated asfollows:

$i = {C\frac{dv}{dt}}$where C is the capacitance of capacitor 308 and dv/dt is the rate ofvoltage change. Thus, if all other design parameters remain the same, amuch smaller value for C will result in a smaller inrush current indirect proportion to how small of a capacitance is selected forcapacitor 308. For example, in some embodiments, capacitor 310 may be analuminum electrolytic capacitor having a capacitance on the order of afew hundred microfarads (e.g., 100 μF, 200 μF, 300 μF, etc.). In suchcases, capacitor 308 may be selected to have a capacitance of only a fewhundred pF or nF. Notably, if the capacitance of capacitor 310 is on theorder of several hundred microfarads and capacitor 308 has a capacitanceof several hundred pF, the inrush current into capacitor 308 will beapproximately 1,000,000 times smaller, given the same dv/dt.

Referring now to FIG. 4, an example graph illustrating the operation ofthe hot swap circuit of FIG. 3 is shown, according to variousembodiments. As shown, switches 304 and 306 may be alternately openedand closed via separate control pulses provided to the switches duringan initial period of time (e.g., between times t₀ and t₁). In variousembodiments, the control circuitry for these pulses may include, but isnot limited to, piezoelectric timers, integrated circuit (IC) timers,flip-flops, microprocessors, application-specific ICs (ASICs), or thelike.

The control pulse supplied to switches 304 and 306 may be alternated ata high enough frequency, to build up a charge across capacitor 310, asshown. In various embodiments, a dead time may be used between thepulses, to ensure that there is no overlap of the pulses during timeperiod t₀-t₁. In other words, the dead times may correspond to periodsof time during which both of switches 304 and 306 are held open. Forexample, assume that the pulse sent to switch 304 has an initial delayof 10 μs, is on for 9 μs, has rise times and fall times of 10 ns, and atotal period of 20 μs. In such a case, the pulse sent to switch 306 mayuse the same parameters, but may have an initial delay of 20μ, to ensurethat the pulses sent to switches 304 and 306 do not overlap, accordingto one example. Other parameters for the pulses may be used in otherembodiments, to ensure that both switches 304, 306 are not closedsimultaneously at any point between times t₀-t₁.

During time period t₀-t₁, the voltage across input capacitor 310 willasymptotically approach that of power source 106. Notably, capacitor 308will be charged by power source 106 when switch 304 is closed. Then,after switch 304 is opened and switch 306 is subsequently closed, thestored energy in capacitor 308 will be transferred to input capacitor310. This process may be repeated any number of times during timest₀-t₁. By using a much smaller capacitor for capacitor 308 than that ofcapacitor 310, the inrush current may also be limited significantly,allowing switches 304-306 to also be reduced in size.

At some point in time, such as at time t₁ or shortly thereafter, thevoltage of input capacitor 310 will be nearly equal to that of powersource 106 (e.g., within some small Δ of power source 106) and the riskof inrush current will be minimal. From this point forward, the controlof switches 304 and 306 may begin a second mode of operation wherebyboth of switches are then closed at the same time, to complete thecharging of capacitor 310 to its final voltage input level (e.g., 50V,etc.). In other words, after time t₁, switches 304-306 may both beclosed, to directly connect input capacitor 310 to power source 106.

Referring now to FIG. 5, a further example hot swap circuit 302 a isshown, according to various embodiments. As shown, hot swap circuit 302a may have a similar configuration and operation as that of hot swapcircuit 302 shown in FIG. 3. However, hot swap circuit 302 a may alsoinclude an inductor 502 in series with capacitor 308 along line 312. Aswould be appreciated, inductor 502 may be a single inductor, multipleinductors in series (e.g., thereby adding the inductances of theinductors), or in parallel, in various embodiments.

The addition of inductor 502 in hot swap circuit 302 a may allow forgreater control of the inrush current to capacitor 308. Notably, therelationship between inductance, voltage, and current is as follows:

$V = {L\frac{di}{dt}}$where V is the voltage across inductor 502, L is the inductance ofinductor 502, and di/dt is the rate of change of the current throughinductor 502. Rearranging this equation gives the following:

$\frac{V}{L} = \frac{di}{dt}$where V and L may be selected as desired, to control the current changeinto and out of capacitor 308. Since inductor 502 is not located alongthe primary power path of hot swap circuit 302 a (i.e., through switches304, 306), inductor 502 may be very small in size (e.g., 1 μH in serieswith a 47 nF capacitor, etc.), while still significantly limiting theinrush current.

In contrast to hot swap circuit 102, hot swap circuit 302 a allows forswitches 304 and 306 to operate outside of the SOA region of that ofswitch 108. Notably, if switch 108 is a MOSFET, it may take severalmilliseconds to turn on, consuming power the entire time. In addition,since the inrush current is relatively large in hot swap circuit 102,switch 108 must be sized accordingly. However, in hot swap circuits 302and 302 a, the inrush current is limited by capacitor 308 (and furtherby inductor 502, if used), allowing switches 304 and 306 to turn onquickly (e.g., on the order of nanoseconds) and to operate outside ofthe SOA region. Thus, switches 304 and 306 may be much smaller FETs thanthat of switch 108, thereby simplifying the construction of the hot swapcircuits and allowing for the use of more readily available components.

Referring now to FIG. 6, an example simplified procedure 600 is shownfor operating a hot swap circuit, according to various embodiments. Ingeneral, procedure 600 may be performed by one or more microcontrollers,one or more application specific integrated circuits (ASICs), one ormore processors executing software, or any other circuitry operable toprovide control signals to the switches of a hot swap circuit (e.g.,switches 304-306 described above, etc.). Procedure 600 may begin at step605 and continue on to step 610 where, as described in greater detailabove, a first switch of a hot swap circuit may be closed to charge afirst capacitor. For example, as described above, switch 304 may beclosed to provide an electrical path from power source 106 to capacitor308. In some embodiment, a second switch of the hot swap circuit may beheld open while the first switch is closed, to allow the electricalenergy to accumulate on the first capacitor.

At step 615, as detailed above, the first switch may be opened. Inparticular, after the first capacitor has been charged, the first switchmay be opened, thereby allowing the energy transferred to the firstcapacitor to remain stored by the first capacitor. During this time, thesecond switch for the hot swap circuit may also be held open for a deadperiod of time, in some embodiments.

At step 620, as described in greater detail above, the second switch maybe closed, to transfer the energy stored by the first capacitor to betransferred to an input capacitor of the hot swap circuit. For example,as detailed above, switch 306 may be closed at some point after openingswitch 304, to transfer the energy stored by capacitor 308 to inputcapacitor 310. Such an input capacitor may be connected to the secondswitch and located in parallel to the input line to a power system, suchas power system 104.

At step 625, as detailed above, the first and second switches may beclosed to complete the charging of the input capacitor. In variousembodiments, steps 610-620 may be repeated any number of times, therebyallowing the voltage across the input capacitor to build to a desiredthreshold voltage level (e.g., near the voltage level of the powersource for the hot swap circuit). When the voltage across the inputcapacitor reaches the desired threshold voltage (e.g., when the threatof a high inrush current is significantly reduced), both switches of thehot swap circuit may be closed, thereby allowing the power source tocomplete charging the input capacitor to its final voltage level.Procedure 600 then ends at step 630.

It should be noted that while certain steps within procedure 600 may beoptional as described above, the steps shown in FIG. 6 are merelyexamples for illustration, and certain other steps may be included orexcluded as desired. Further, while a particular order of the steps isshown, this ordering is merely illustrative, and any suitablearrangement of the steps may be utilized without departing from thescope of the embodiments herein.

The techniques herein, therefore, provide for hot swap circuit designsthat do not require large, specialized SOA FETs. Instead, theswitches/FETs used in the designs herein may be considerably smallerthan SOA-operation FETs, less expensive, and more readily available fromsuppliers. In addition, the designs herein can be easily scaled for usein higher power boards and do not require complex control circuitry toprotect the FET(s) from damage from operating in the sensitive SOAregion.

The foregoing description has been directed to specific embodiments. Itwill be apparent, however, that other variations and modifications maybe made to the described embodiments, with the attainment of some or allof their advantages. For instance, it is expressly contemplated thatcertain components and/or elements described herein can be implementedas software being stored on a tangible (non-transitory)computer-readable medium (e.g., disks/CDs/RAM/EEPROM/etc.) havingprogram instructions executing on a computer, hardware, firmware, or acombination thereof. Accordingly this description is to be taken only byway of example and not to otherwise limit the scope of the embodimentsherein. For example, the size of the components described herein may besized by one skilled in the art based on the desired source voltage anddesired initial voltage drop across the switch of the hot swap circuit,without deviating from the teachings herein. Therefore, it is the objectof the appended claims to cover all such variations and modifications ascome within the true spirit and scope of the embodiments herein.

What is claimed is:
 1. A hot swap circuit comprising: a first switchconnected to a power input line; a first capacitor connected to thefirst switch that is charged when the first switch is closed; a secondswitch connected to the first switch and the first capacitor; and aninput capacitor connected to the second switch and located in parallelwith an input line to a power system, wherein the input capacitor ischarged by the first capacitor when the second switch is closed andwherein the first switch and the second switch are controlled toalternately open and close during charging of the input capacitor. 2.The hot swap circuit as in claim 1, further comprising circuitryoperable to alternate between closing the first and second switches by:closing the first switch while holding the second switch open, to chargethe first capacitor; and closing the second switch while holding thefirst switch open, to transfer charge from the first capacitor to theinput capacitor.
 3. The hot swap circuit as in claim 2, wherein thecircuitry is operable to hold the first and second switches open for adead period of time, prior to closing either the first switch or thesecond switch.
 4. The hot swap circuit as in claim 2, wherein thecircuitry is further operable to: close both switches, after apredefined period of time.
 5. The hot swap circuit as in claim 4,wherein the predefined period of time corresponds to a voltage level towhich the input capacitor has been charged, and wherein the inputcapacitor is charged from the voltage level to a final input voltagelevel after both switches are closed.
 6. The hot swap circuit as inclaim 5, wherein the final input voltage is 50 volts.
 7. The hot swapcircuit as in claim 1, further comprising: an inductor located in serieswith the first capacitor between the first capacitor and the firstswitch.
 8. The hot swap circuit as in claim 1, wherein the firstcapacitor has less capacitance than that of the input capacitor.
 9. Thehot swap circuit as in claim 1, wherein the first and second switchescomprise metal-oxide semiconductor field effect transistors (MOSFETs).10. The hot swap circuit as in claim 1, wherein the input capacitor isan aluminum electrolytic capacitor.
 11. The hot swap circuit as in claim1, further comprising the power system, wherein the power system isconfigured to step down an input voltage to one or more lower voltages.12. The hot swap circuit as in claim 11, wherein the power systemcomprises: a plurality of point of load converters.